FR2702881A1 - Colour cathode-ray tube containing a perforated mask in which holes are arranged with a pitch which does not decrease monotonically - Google Patents

Abstract

The invention relates to a colour cathode-ray tube. In a perforated mask (5) used in a cathode-ray tube, the holes (12) are arranged with a variable pitch which does not generally decrease monotonically from a central part towards two opposite peripheral parts of the mask when looking in the horizontal direction of the tube, in any position on the said mask in the vertical direction, with substantially zero increase of the said pitch in first regions, and has a gradient of not less than zero in the second regions. Application in particular to colour television sets.

Description

 The present invention relates to a perforated mask comprising holes arranged with a variable distribution pitch, that is to say not constant, and intended to be used in a color cathode ray tube, and a color cathode ray tube comprising such a mask perforated.

 Generally, a color cathode ray tube for displaying a color video image is constituted by a panel-shaped part comprising a luminescent screen formed on the inner surface of the front plate, a neck-shaped part, in which is arranged an electron gun for producing three electron beams, and a funnel-shaped part for connecting the panel-shaped part and the neck-shaped part. The funnel-shaped part is equipped with a deflecting device used to deflect the electron beams emitted by the electron gun by causing these beams to scan the luminescent screen.

 The electron gun has different electrodes such as cathode electrodes, control electrodes, focusing electrodes and accelerating electrodes. The three electron beams emitted by the cathode electrodes are modulated by image signals, which are applied to the control electrodes, then pass through the focusing electrodes and the accelerating electrodes, which apply energies to them. The excited electron beams meet the luminescent screen. During the period, during which the three electron beams are emitted by the electron gun and reach the luminescent screen, they are deflected horizontally and vertically by the deflection device, which is provided on the funnel-shaped part, then, as is well known, pass through holes made in the shadow mask to form a color video image on the luminescent screen, which is arranged just behind the shadow mask. In this case, the shadow mask is produced with a curved surface such that it adapts to a curved surface (slightly spherical shape) of the front plate of the panel-shaped part, and the distribution pitch of the holes which are formed in the shadow mask is determined according to this curved surface.

 Figures la and lb, which are annexed to the present application, are diagrams, to which reference will be made to explain how one can determine the horizontal pitch distribution of the holes in the shadow mask. Figure la shows a cross-sectional view of part of the interior of the panel-shaped part of a color cathode ray tube, and figure lb shows a plan view of part of the mask.

 In FIGS. 1 a and 1 b, the reference number 50 designates a front plate of the panel-shaped part, the reference number 51 a perforated mask, the reference number 52 an axis of the tube, the reference number 53 a beam of electrons, the reference numeral 54 a center of deflection of the electron beam 53, the reference numeral 55 of the slot-shaped holes provided for the passage of the electron beams, and the reference numerals 560, 561, 562, 563, ..., 56nul '56nit 56nul 56n + 2 the vertical axes connecting the respective holes 55 for passage of the electron beams.

 In the panel-shaped part of the cathode ray tube, the shadow mask 51 made with a slightly spherical curved surface is arranged substantially parallel and opposite the front plate 50, which is also made similarly with a curved surface slightly spherical. The electron beam 53 emitted by the electron gun (not shown) is transmitted along the axis 52 of the tube, is for example deviated horizontally at the level of the center of deflection 54, then is projected through the shadow mask 51 on the luminescent screen (not shown) which is arranged on the front plate 50.

 Here, the distance between the shadow mask 51 and the front plate 50 along the path of the electron beam 53 is represented by bnr the distance between the deflection center 54 and the front plate 50 is designated by dn, the pitch (pitch hole distribution) of the vertical central axes 56nul 56n is designated by year, and the constant to be determined by the deflection device (not shown) is designated by S. Then we can express the distance bn by means of the relation bn = an.dn / 3S, or this distance satisfies the relation bon an.Therefore, the distance bn is present over the entire surface of the shadow mask 51, and the shape of the shadow mask 51 is determined so that this distance bn varies uniformly or continuously over the entire surface, and the pitch for the distribution of the holes in each part is determined according to the shape of the mask.

 In this case, the shape of the known shadow mask 51 is designed such that the radius of curvature at the periphery (represented by R2) is slightly less than the radius of curvature present at the center (represented by R1), or that we have R1> R2. Consequently, the pitch of a large number of electron beam passage holes, which are provided in the shadow mask 51, gradually increases from the center towards the periphery.

 The shadow mask 51 is generally formed by a thin iron plate having a thickness of about 0.1 to 0.3 mm, and is shaped so that its entire surface is slightly spherical like that has been described previously. Since the entire mask is formed by a thin iron plate, its resistance is not sufficient and therefore in this mask there are various known problems which will be described below.

 When the electron beam 53 meets the shadow mask 51, the latter undergoes thermal expansion under the action of the heat appearing under the effect of the shock. As a result, the path or trajectory of the electron beam 53 is changed, which results in a reduction in purity, and a so-called "dome deformation" effect occurs. In addition, the shadow mask 51 can resonate with the sound (in particular delivered by a loudspeaker) produced by the television receiver or a vibration, which leads to a reduction in purity or what is called a stridulation. In addition, the perforated mask 51 is deformed under the effect of a shock during the process of manufacturing the cathode-ray tube in colors or during its transport, which results in a reduction in purity.

 A color cathode ray tube has been proposed, the perforated mask of which is designed so that the distance between adjacent columns of holes in the perforated mask is maximum or greatest in its central part and in an end part, and the weakest of these parts, as described in Japanese patent application JP-A-59-165341 (put to public inspection on September 18, 1984).

 An object of the present invention is to provide a shadow mask which is suitable for use in a color cathode ray tube and which has improved mechanical strength so that it cannot deform under the effect of the dome deformation, stridulation and / or shock.

 Another object of the invention is to provide a color cathode ray tube which uses the aforementioned shadow mask.

 In accordance with one aspect of the present invention, there is provided a shadow mask for use in a color cathode ray tube, comprising a metal plate in which a plurality of holes are provided to allow passage of electron beams through the tube cathodic in colors, characterized in that said holes are arranged with a variable distribution pitch, which generally does not decrease monotonically from a central part towards two opposite peripheral parts of said shadow mask when looking in a first direction which corresponds to a horizontal direction of the color cathode ray tube, in any position on said second mask in a second direction perpendicular to said first direction. An increase in the variable distribution pitch in said first direction is substantially zero in first regions located between said part hundred rale and intermediate parts located between the central part and the two opposite peripheral parts of said shadow mask, and has a gradient not less than zero in second regions located between the intermediate parts and opposite peripheral parts of said shadow mask.

 The expression "no distribution" of the holes in the shadow mask designates the center-to-center distance between adjacent holes or between alternately adjacent holes.

 According to another aspect of the invention, a color cathode-ray tube is provided which comprises an envelope comprising a panel-shaped part, a neck-shaped part and a funnel-shaped part which connects the panel form and the neck-shaped part, a shadow mask arranged opposite a luminescent screen formed on the inner face of the panel-shaped part, and an electron gun mounted in the neck-shaped part so as to emit electron beams towards the screen, and a deflection device provided around the junction between the neck-shaped part and the funnel-shaped part so as to deflect each of the beams electrons by causing it to perform a scan of the luminescent screen, the shadow mask comprising holes for passage of the electron beams, the horizontal distribution pitch of which is substantially constant in the first regions located between re a central part and intermediate parts which are located between the central part and peripheral parts, and increases rapidly in second regions located between the central part and the peripheral parts.

 In accordance with the structure indicated above, the shadow mask intended for use in a color cathode ray tube has a radius of curvature in cross section which has a substantially constant value in the regions which extend from the central part and its vicinity up to to the intermediate parts and their vicinity, but which has a radius of curvature which is reduced in the regions which extend from the intermediate parts and from their vicinity to the peripheral parts and their vicinity from the intermediate parts towards the peripheral parts. in other words, if the radius of curvature in the central part of the shadow mask and in its vicinity is designated by R1 and if the radius of curvature in the peripheral parts and in their vicinity is designated by R2, the shadow mask can be shaped so that we have R1 R2. The mechanical resistance of this perforated mask is greater than that of the known perforated mask, which has the effect that the perforated mask is less deformed by an impact or the like and is less subject to the effect of domed deformation and of stridulation, and a color cathode ray tube can be produced with such a shadow mask.

Other characteristics and advantages of the present invention will emerge from the description given below taken with reference to the appended drawings, in which
- Figures la and lb, which have already been mentioned, are diagrams to which reference has been made to explain how the horizontal pitch distribution of the holes in the shadow mask is determined;
- Figure 2 shows a schematic view of the structure of the color cathode ray tube of an embodiment of the present invention;
- Figures 3a and 3b are diagrams of the structure of part of the shadow mask of an embodiment of the present invention, intended for use in the color cathode ray tube shown in Figure 2;
- Figure 4 shows a diagram of a horizontal cross section of the shadow mask for use in the color cathode ray tube shown in Figure 2; and
- Figure 5 is a diagram showing the relationship between the horizontal distance from the central part and the horizontal hole distribution pitch.

 Figure 2 is a longitudinal cross-sectional diagram of a color cathode ray tube according to an embodiment of the invention. Referring to Figure 2, there is shown a panel-shaped part 1, a funnel-shaped part 2, a neck-shaped part 3, a luminescent screen (image forming screen) 4, a shadow mask 5, magnetic shielding 6, deflection collar 7, purity adjustment magnet 8, magnet for adjusting the central beam static convergence, a magnet 10 for adjusting the lateral beam static convergence , an electron gun 11, a central beam Bc and two lateral beams Bs.

 The panel-shaped part 1 located on the front of the color cathode ray tube is connected to the neck-shaped part by the funnel-shaped part 2. These parts constitute an envelope made for example of glass as a whole . The luminescent screen 4 is formed on the inner face of the front plate of the panel-shaped part 1, and the shadow mask 5 is arranged opposite the rear face of the luminescent screen 4. In this In this case, the front plate and the shadow mask 5 are each made with a slightly curved surface (having a spherical shape with a large radius of curvature). The magnetic shielding 6 is provided behind the shadow mask 5, and the deflection collar 7 is arranged around the junction between the funnel-shaped part 2 and the neck-shaped part 3, outside the envelope. .In the neck-shaped part 3 is arranged the electron gun 11 which is used to emit the single central beam Bc and two lateral beams Bs, and the magnet 9 for adjusting the static convergence of the central beam and the magnet 10 for adjusting the static convergence of the lateral beams are arranged outside the neck-shaped part.

 Figures 3a and 3b are construction diagrams of part of an example of the shadow mask for use in the color cathode ray tube of this embodiment. Figure 3a shows a shadow mask with elongated holes and Figure 3b shows a shadow mask with circular holes.

 FIGS. 3a and 3b, an axis lla (lla ') of the tube has been shown, holes in the form of slots 12 through which the electron beams pass, circular holes 13, through which the electron beams pass, vertical central axes 140, 141, 142, 143 ... 14nul '14nr 14n + 1, 14n + 2, which connect the centers of the respective holes in the form of slots 12 for the passage of electron beams, vertical central axes 15 15 153 154, ... 15n-2 '15n Ir 15nr 15n + l' 15n + 2 'which connect the centers of the respective circular holes 13.In addition, similar elements corresponding to those shown in Figure 2 are identified by the same reference figures.

 As shown in Figure 3, the shadow mask 5 having elongated holes has a plurality of slot-shaped holes 12 for the passage of electron beams, which are arranged along each of the vertical central axes 140 , 141, 142, 143, ... 14n-1, l4nr 14n + 1, 14n + 2 In this case, when the slot-like holes 12 for the passage of electron beams are formed, the distance (no distribution) between the central axis 140, which is closest to the central part of the mask 5, and the immediately following central axis 141 is designated by a1, the distance (no distribution) between the central axis 141 and the central axis immediately following 142 is designated by a2, the distance (no distribution) between the central axis 142 and the central axis immediately following 143 is designated by a37 ..., the distance (no distribution) between l central axis 14n-1 and the central axis immediately following 14n is designated pa r an, the distance (no distribution) between the central axis 14n and the central axis immediately following 14n + 1 is designated by year + 1, and the distance (no distribution) between the central axis 14n + 1 and the central axis immediately following 14n + 2 is designated by year + 2.

 As shown in FIG. 3b, the shadow mask 5 ′ having circular holes has a plurality of circular holes 13 for the passage of the electron beams, which are arranged along each of the vertical central axes 150, 151, 152 , 153, 154 ...

15n-2 '15n-1 l5nr 15n + 1, 15n + 2- In this case, when the

Claims (6)

circular holes 13 for the passage of electron beams are formed, the distance (no distribution) between the central axis 150, which is closest to the central part of the shadow mask 5 ', and the central axis immediately following 152 is designated by a'2, the distance (no distribution) between the central axis 152 and the immediately following central axis 154 is designated by al4, ..., the distance (no distribution) between the central axis 15nul and the central axis immediately following 15n is designated by a'n, and the distance (no distribution) between the central axis 15n and the central axis immediately following 15n + 2 is designated by alum + 2. The shadow mask 5, 5 'of the cathode ray tube of the embodiment, which has a slightly spherical shape (having a very large radius of curvature) has a shape different from the known shadow mask of this type as described below. In addition, due to this difference in shape, the horizontal pitch of the holes 12, 13 in the shadow mask 5 'differs from that of the known shadow mask. Since the other embodiments are identical to the known cathode ray tube of this type, the operation of the cathode ray tube of this embodiment will not be described. Figure 4 shows a cross-sectional view, viewed in the horizontal direction, of the shadow mask shown in Figure 3a or 3b. In Figure 4, the elements, which correspond to the same elements in Figures 3a and 3b, are designated by the same reference numerals. In the cross-sectional view of the shadow mask 5, 5 ', the radius of curvature can be adjusted to a substantially constant value, namely a relatively high value in the first regions which extend from the central part P0 of the mask and its vicinity to the intermediate parts P1 (P'1) and their vicinity, which are located between the central part P0 and the peripheral parts P2 (P'2), this value however gradually decreasing in the second regions which extend from the intermediate parts P1 (P'1) and their vicinity to the peripheral parts P2 (P'2) and their vicinity when the distance from the peripheral parts P2 (P'2) decreases. This is why, if the radius of curvature in the central part P0 and its vicinity is designated by R1 and if the radius of curvature present in the peripheral parts P2 (P'2) and their vicinity is designated by R2, then the shadow mask can be shaped so satisfy the condition R1 R2. On the other hand, the radius of curvature in the cross section of the known shadow mask decreases relatively uniformly in the direction which extends from the central part and its vicinity in the direction of the peripheral parts. the radius of curvature in the central part and its vicinity is designated by R1 and if the radius of curvature in the peripheral parts and their vicinity is designated by R2, then the known shadow mask is shaped so as to satisfy the condition R1> R2 . According to the arrangement of this embodiment, compared to the conventional shadow mask, the mechanical strength can be increased and therefore the shadow mask cannot be deformed by impact or the like, and the domed deformation effect and stridulation can be reduced. PRIOR ART 1,801 1,602 PRESENT EMBODIMENT 2,072 1,044 R1 (mm) R2 (mm) Examples of the radii of curvature R1 and R2 will be indicated below in accordance with this embodiment, as well as the radii of curvature corresponding to the prior art. In this respect, the perforated masks, which have the radii of curvature R1 and R2, are those intended to be used in a wide cathode ray tube of television (long laterally) and having a diagonal length equal to 76 cm, with Ph2 = 1 , 25 Phg Figure 5 is a graph showing the relationship between the horizontal distance from the central part at any vertical level on the shadow mask and the horizontal pitch distribution of holes at corresponding distances on the shadow mask of embodiment of the invention. The abscissas represent the distance from the central part, and the ordinates represent the horizontal distribution step. In FIG. 5, curve 17 indicates an example of the distribution pitch of the holes in the shadow mask 5 (5 ′) intended to be used in the cathode-ray tube according to the present invention, and curve 18 represents an example of the distribution pitch holes in the known shadow mask. In FIG. 5, it can be seen that the pitch distribution of the holes of the conventional perforated mask, as represented by FIG. 18, gradually increases in the regions which extend from the central part P0 of the perforated mask and its vicinity up to peripheral parts P2 (P'2) when the distance from the central part increases. In other words, if we use the distribution steps a1, a2, a3, an, an + l, an + 2 as shown in Figures 3a and 3b, the conditions al <a2 <a37 an <an + 1 < year + 2 must be satisfied. On the contrary, the hole distribution pitch for the shadow mask 5 (5 ') of this embodiment is constant or increases monotonically in the region which extends from the central part P0 of the shadow mask 5 (5 ') and its vicinity in the direction of the peripheral parts P2 (P'2). In this case, the hole distribution pitch is substantially constant for the first regions from the central part P0 of the shadow mask 5 (5 ') and its vicinity in the direction of the intermediate parts P1 (P'l) which are located between the part central P0 and the peripheral parts P2 (P'2), and increase relatively rapidly for the second regions which extend from the intermediate parts P1 (P'1) towards the peripheral parts P2 (P'2) when the distance to from the central part increases. In other words, if the distribution steps a1, a27 a3 are those (Phg) present in the central part PO and its vicinity and if the distribution steps an, an + l and an + 2 are those (Ph2) present in the peripheral parts P2 (P'2) and their vicinity, then the conditions a1 ~ a2 1 a3 and an <an + l <an + 2 must be satisfied. The hole distribution pitch in the second regions must have a constant or increased gradient (rate of increase). The expression "the hole distribution pitch is substantially constant" for the first regions indicated above is intended to indicate that, assuming that the distribution pitch in the central part P0 of the shadow mask or in the vicinity of this part is Phg, the no distribution of the holes Ph1 is substantially in a range between Phg and 1.005 Ph0. P2 (P'2) (one half of the effective horizontal width of the mask) is Lx, the distance between the part P0 and the part P1 (P'1) should be between approximately Lx / 3 and approximately 2tex / 3 and more preferably should be approximately Lux / 2. In this case, it is preferable that the distribution pitch Ph2 in the part P2 (P2 ') is between 1.1 Ph figure 5. In addition, the "intermediate parts P1 (P'1)" are supposed to indicate a part of the shadow mask, in which the hole distribution pitch begins to increase relatively rapidly from a value of Ph1 (the distribution pitch for the first regions, which takes a value situated in a range between Phg and 1.005 Phg as indicated above, and represented as being equal to 1.005 Phg in FIG. 5). Furthermore, supposing that the distance between the part P0 and the part Si the distance between the point P0 and the point P1 (P1,) is much greater than 2Lx / 3 , the effect of reduction of the domed bulge in the intermediate parts P1 (P1,) or in the vicinity of these parts is small, whereas if the distance is much less than Lx / 3, one cannot expect a significant increase in the mechanical strength of the ma sque perforated. This is why, in accordance with this embodiment, the radius of curvature in the cross section of the shadow mask 5 (5 ') of the color cathode ray tube can be chosen to be substantially constant in the region extending from the central part and its neighborhood towards the peripheral parts and their vicinity, but gradually decreases in the regions extending from the intermediate parts towards the peripheral parts, and the relationship between the radius of curvature R1 in the central part of the mask and its vicinity and the radius of curvature R2 in the peripheral parts and their vicinity can satisfy the condition R1 R2. Consequently, the mechanical resistance can be increased and consequently the perforated mask cannot deform and the effects of deformation in dome and stridulation can be reduced. intermediate and peripheral parts. increased in fourth regions located between the parts having a constant or intermediate gradient (rate of increase), r and can be adjusted so as to be between the central part of the mask and substantially zero parts in third regions located indicated above, can be set to a value as described in the embodiment of hole distribution in the horizontal direction, perforated mask in the vertical direction as well as the beam pitch, the hole distribution pitch for the increase of said second variable distribution step in said second direction has a gradient of not less than zero in fourth regions located between said second intermediate parts and said second opposite peripheral parts of said mask. an increase in said second variable pitch of distribution in said second direction is substantially zero in third regions located between said central portion and second intermediate portions located between said central portion and said two opposite second peripheral portions of said mask, and and looks into said second direction, in any position on said mask in said first direction, opposite peripherals of said shadow mask when the central part in the direction of two second parts generally does not decrease monotonously from said a second variable pitch of distribution which of a perforated manner in which the holes are further arranged according to Thus, there is provided according to the invention, a mask CLAIMS  1. A shadow mask intended to be used in a color cathode ray tube, comprising a metal plate in which a plurality of holes (12, 13) are provided to allow the passage of electron beams (53) in the color cathode ray tube , characterized in that said holes are arranged with a variable distribution pitch, which generally does not decrease monotonically from a central part (P0) in the direction of two opposite peripheral parts (P2) of said shadow mask when we look in a first direction which corresponds to a horizontal direction of the color cathode ray tube7 in any position on said second mask in a second direction perpendicular to said first direction, and  that an increase in said variable distribution pitch in said first direction is substantially zero in first regions located between said central part (P0) and intermediate parts (P1) located between said central part and said two opposite peripheral parts of said mask; and  that an increase in said variable pitch of distribution in said first direction has a gradient not less than zero in second regions located between said intermediate parts and said opposite peripheral parts of said mask.  2. A shadow mask according to claim 1, characterized in that said holes (13) are substantially circular.  3. A shadow mask according to claim 1, characterized in that said holes (12) are substantially in the form of slots.  4. shadow mask according to claim 1, characterized in that said holes are further arranged in a second variable distribution pitch which generally does not decrease monotonically from said central part towards two opposite second peripheral parts of said shadow mask when looking in said second direction, in any position on said mask in said first direction, and  that an increase in said second variable distribution pitch in said second direction is substantially zero in third regions located between said central part and second intermediate parts located between said central part and said two opposite second peripheral parts of said shadow mask, and  that an increase in said second variable distribution step in said second direction has a gradient not less than zero in fourth regions located between said second intermediate parts and said second opposite peripheral parts of said mask.  5. Color cathode ray tube including  an envelope having a panel-shaped part (1), a neck-shaped part (3) and a funnel-shaped part (2) interconnecting said panel-shaped parts and neck;  an electron gun (11) mounted inside said neck-shaped portion for producing electron beams (BC, Bs);  a luminescent screen (4) formed on an interior surface of said panel-like portion; and  a shadow mask (5) in which are formed a plurality of holes (12, 13) and which is mounted on the rear face of said luminescent screen so that said electron beams pass through holes in said shadow mask to strike said luminescent screen,  characterized in that  said holes are arranged with a variable distribution pitch which generally does not decrease monotonically from a central part (P0) towards the two opposite peripheral parts (P2) of said shadow mask when looking in a horizontal direction the cathode ray tube, in any position on said shadow mask in a vertical direction inside the color cathode ray tube, and  that an increase in said variable distribution pitch in said horizontal direction is substantially zero in first regions located between said central part (P0) and intermediate parts (P1) located between said central part and said two opposite peripheral parts (P2) of said shadow mask, and  that an increase in said variable pitch of distribution in said horizontal direction has a gradient of not less than zero in second regions located between said intermediate parts and said opposite peripheral parts of said perforated mask.  6. Color cathode ray tube comprising a shadow mask according to any one of claims 1 to 4.